Butt connection for hollow profile members

ABSTRACT

A butt connection of divided hollow profile members, which is suitable in particular for rotor blades of wind power installations, comprises a multiplicity of straps which are arranged along the join and which bridge over same and which are respectively fixed with their ends to one of the profile members to be connected. In this respect the arrangement is preferably such that one of the two bolts fixing the strap at the ends thereof has a wedge-shaped flattening, by means of which a tensile prestressing can be imparted to the strap.

The invention concerns a butt connection for divided hollow profile members, in particular for rotor blades of wind power installations.

Similarly to aircraft propellers, the rotors of wind power installations have rotor blades comprising a load-bearing spar or beam member—in most cases with an upper and a lower flange—and a hollow profile member which determines the aerodynamic properties of the rotor. Nowadays the hollow profile members generally comprise composite materials, namely glass or carbon fibers with polyester or epoxy resins as binders. What has become the usual practice is producing the rotor blade hollow profile members (whose cross-section generally changes over the length thereof) in the form of two longitudinally divided half-shell portions which are assembled to the spar to form the finished blade.

With the increasing power of modern wind power installations, the rotors thereof are also becoming larger in diameter, which requires the production of correspondingly longer rotor blades. If the production of such long rotor blades, that is to say the half-shell portions required for same, in one piece, is already not without its problems (inter alia because of the correspondingly large factory building), transportation which is then required to the location at which the wind power installation is erected represents a serious obstacle.

Having regard thereto and having regard to the foreseeable further increase in the length of rotor blades for wind power installations, consideration is to be given to transversely dividing rotor blades of that kind and in that respect more specifically the hollow profile members thereof, transporting them separately, and only finishing the rotor blades at the location of erection of the wind power installation, by assembling the individual parts at their butt joins. The problem which arises out of that approach however is that of developing a butt connection which does not seriously influence the aerodynamic properties of the rotor blade, which is of low weight, and which in particular is capable of withstanding the considerable fluctuating loads to which the rotor blades are exposed in operation of a wind power installation.

The invention resolves that problem by a multiplicity of bars or straps which are arranged along the join line and which bridge over same and which are fixed with their ends respectively to one of the profile member parts to be connected. The straps or bars replace entirely the one-piece flange connection conventionally usual for connecting hollow profile members; they are substantially lighter than that and can be arranged distributed over the periphery of the hollow profile member discretely at different spacings from each other, namely in dependence on the forces to be transmitted at the join line, so that the design of the connection—with very good application of the forces involved—is simpler in terms of its operating strength, than when using a conventional flange/screw connection. Although this kind of connection can also be used for longitudinally divided hollow profile members (rotor blades), it is suitable in particular for transversely divided hollow profile members of non-round cross-section, with the bars or straps being arranged at the periphery of the hollow profile member.

The freedom from maintenance of the new butt connection is of particular advantage because the connection is not self-releasing and therefore there are no prestressing losses that also have to be tolerated.

Preferably each strap connection comprises double bars or straps with a respective bar or strap arranged on the outside and on the inside of the hollow profile member. In addition it is advantageously provided that each strap can be prestressed with a defined tensile force. A sufficiently high tensile force prestressing provides that, in spite of an alternate loading (tensile force/compression force) in the course of a revolution of the rotor, the situation at the butt connection still remains one involving tensile forces and it is only the magnitude of such forces that changes over the course of a revolution.

In order to apply the tensile force prestressing required for that purpose to the individual straps which jointly form the butt connection, it is preferably provided that each strap is fixed to the hollow profile member parts by means of two bolts and at least one of the bolts, in the respective contact region with the strap or straps, has a wedge-shaped flattening in its axial direction and is held non-rotatably. Alternatively the bolt could also be of a part-conical configuration, and then it can also be rotated. At any event, when fixing the straps, when they are pushed with their (suitably configured) ends over the bolt and urged in a direction towards the surface in question of the hollow profile member, at the same time tensile force prestressing is built up in the longitudinal direction of the strap and thus perpendicularly to the join line. In order to implement that in a simple fashion, the bolt advantageously comprises a sleeve provided with the wedge-shaped flattenings, and a screw which passes axially through the sleeve and which has a nut, wherein both the screw head and also the nut press by means of cup-like pressure portions against the associated strap and prestress same by movement along the wedge surface (or cone surface).

A further alternative form of the prestressing mechanism can provide that at least one of the bolts, in the respective contact regions with the straps, has a bulge which is eccentric with respect to its axis. By rotating the bolt—which moreover does not need to be rotated to fix the straps—it is also possible in that way to produce the desired tensile force prestressing in the strap.

The drawing illustrates the invention by means of an embodiment. In the drawing:

FIG. 1 shows a plan view of a (singly) transversely divided rotor blade for the rotor of a wind power installation in the form of a diagrammatic cross-section (the gap between the parts serves only for enhanced clarity of the drawing),

FIG. 2 shows a plan view of the portion x of the butt connection according to the invention between the two rotor blade parts in FIG. 1,

FIG. 3 shows a perspective view of the entire butt connection between the two rotor blade parts in FIG. 1, but which is opened up as in FIG. 1,

FIG. 4 is a view in longitudinal section on an enlarged scale through one of the strap connections forming the butt connection in the entirety thereof,

FIG. 5 shows a plan view of the strap connection in FIG. 4, and

FIG. 6 shows a partial view taken along line A-A in FIG. 4.

FIG. 1 is a diagrammatic view in cross-section of a transversely divided rotor blade of a wind power installation. The join 2 between the parts 1 a and 1 b of the rotor blade 1 is open. The two rotor blade parts 1 a and 1 b comprise a load-bearing core profile member 3 and an aerodynamically shaped shell portion 4.

FIG. 2 is a plan view showing a part of the butt connection between the parts 1 a and 1 b of the rotor blade 1 when the join 2 is closed. The butt connection comprises a plurality of bars or straps 5 which bridge over the join 2 and which are respectively fixed by means of bolts 6 a, 6 b to both rotor blade parts 1 a, 1 b.

In FIG. 3—as in FIG. 1—the join 2 is opened, and portions of the two rotor parts 1 a, 1 b are shown in a perspective view. The bars or straps 5 are also cut away (only for the purposes of clearer illustration) and the overall view of the (opened) butt connection shows how the straps 5 with their bolts 6 a, 6 b are distributed over the—non-round—cross-section of the divided hollow profile member. The arrangement of the straps 5 is at its densest in the region of the core profile member 3 because it is there that the highest transmission of forces occurs; in the other regions, there are larger spacings between the straps 5.

FIGS. 4 to 6 show a strap connection in detail. A respective strap 5 is arranged above and below the hollow profile member parts 1 a, 1 b. Both straps 5 are fixed to the part 1 b by means of a bolt 6 b, with the interposition of washers 7, by a screw 8 with nut 9. Fixing of the straps 5 to the part 1 a is similar, but the bolt 6 a has wedge-shaped flattened portions 10 which taper from the center of the bolt towards its ends and towards the axis 11 of the (longer) screw 8 with nut 9. Cup-like pressure portions 12 are provided between the head of the screw 8 and the strap 5 adjacent thereto on the one hand and between the nut 9 and the strap 5 adjacent thereto on the other hand. When the screw 8 with the nut 9 is tightened, the pressure portions 12 exert corresponding forces on the straps 5; the approach movement thereof, in particular towards the profile member part 1 a, causes them to slide upwardly along the flattened portions 10 of the bolt 6 a, whereby a tensile stress is built up in the straps 5 (in the contact regions of the straps 5 with the flattened portions 10, the inside wall of the straps 5 can be adapted to the surfaces of the flattened portions 10). The tensile stress in the straps 5 results in a closing pressure stress applied to the hollow profile parts 1 a, 1 b in the region of their join 2. 

1-7. (canceled)
 8. A blade for a wind turbine, the blade having a hollow profile and having a root portion adjacent to a rotor hub and a tip portion spaced away from the rotor hub, the blade extending from the rotor hub to its tip end, the blade comprising: a first rotor blade part having a first end positioned between a tip of the blade and the rotor hub of the wind turbine and a second end spaced longitudinally along the rotor blade away from the first end, positioned closer to the tip of the blade than the first end; a second rotor blade part having first end abutting with the second end of the first rotor blade part; a plurality of first fixtures coupled to the second end of the first rotor blade part; a plurality of second fixtures coupled to the first end of the second rotor blade part; a plurality of connecting members that extend from a respective first fixture on the first rotor blade part to a respective second fixture on the second rotor blade part, the connecting members having a tensile stress placed thereon to apply a closing pressure between the first rotor blade part and the second rotor blade part to form a rotor blade portion composed of the two parts having a butt joint at which they are held together by the connecting members.
 9. The rotor blade according to claim 8 wherein some of the first and second fixtures are on an outside surface of the first and second parts, respectively and some of the first and second fixtures on an inside surface of the first and second parts, respectively, to provide the connecting members on the outside and on the inside of the blade.
 10. The rotor blade according to claim 8 wherein the spacing between adjacent first fixtures is smaller at curved region near the leading edge of the rotor blade than it is at flat regions near the trailing edge of the rotor blade. 